A Recombinant Attenuated Yersinia pseudotuberculosis Vaccine Delivering a Y. pestis YopENt138-LcrV Fusion Elicits Broad Protection against Plague and Yersiniosis in Mice.

In this study, a novel recombinant attenuated Yersinia pseudotuberculosis PB1+ strain (χ10069) engineered with ΔyopK ΔyopJ Δasd triple mutations was used to deliver a Y. pestis fusion protein, YopE amino acid 1 to 138-LcrV (YopENt138-LcrV), to Swiss Webster mice as a protective antigen against infections by yersiniae. χ10069 bacteria harboring the pYA5199 plasmid constitutively synthesized the YopENt138-LcrV fusion protein and secreted it via the type 3 secretion system (T3SS) at 37°C under calcium-deprived conditions. The attenuated strain χ10069(pYA5199) was manifested by the establishment of controlled infection in different tissues without developing conspicuous signs of disease in histopathological analysis of microtome sections. A single-dose oral immunization of χ10069(pYA5199) induced strong serum antibody titers (log10 mean value, 4.2), secretory IgA in bronchoalveolar lavage (BAL) fluid from immunized mice, and Yersinia-specific CD4+ and CD8+ T cells producing high levels of tumor necrosis factor alpha (TNF-α), gamma interferon (IFN-γ), and interleukin 2 (IL-2), as well as IL-17, in both lungs and spleens of immunized mice, conferring comprehensive Th1- and Th2-mediated immune responses and protection against bubonic and pneumonic plague challenges, with 80% and 90% survival, respectively. Mice immunized with χ10069(pYA5199) also exhibited complete protection against lethal oral infections by Yersinia enterocolitica WA and Y. pseudotuberculosis PB1+. These findings indicated that χ10069(pYA5199) as an oral vaccine induces protective immunity to prevent bubonic and pneumonic plague, as well as yersiniosis, in mice and would be a promising oral vaccine candidate for protection against plague and yersiniosis for human and veterinary applications.

Purification and characterization of a recombinant Yersinia pestis V-F1 "Reversed" fusion protein for use as a new subunit vaccine against plague.

We previously developed a unique recombinant protein vaccine against plague composed of a fusion between the Fraction 1 capsular antigen (F1) and the V antigen. To determine if overall expression, solubility, and recovery of the F1-V fusion protein could be enhanced, we modified the original fusion. Standard recombinant DNA techniques were used to reverse the gene order such that the V antigen coding sequence was fused at its C-terminus to the N-terminus of F1. The F1 secretion signal sequence (F1S) was subsequently fused to the N-terminus of V. This new fusion protein, designated F1S-V-F1, was then co-expressed with the Y. pestis Caf1M periplasmic chaperone protein in BL21-Star Escherichia coli. Recombinant strains expressing F1-V, F1S-F1-V, or F1S-V-F1 were compared by cell fractionation, SDS-PAGE, Western blotting, and suspension immunolabelling. F1S-V-F1 exhibited enhanced solubility and secretion when co-expressed with Caf1M resulting in a recombinant protein that is processed in a similar manner to the native F1 protein. Purification of F1S-V-F1 was accomplished by anion-exchange and hydrophobic interaction chromatography. The purification method produced greater than 1mg of purified soluble protein per liter of induced culture. F1S-V-F1 polymerization characteristics were comparable to the native F1. The purified F1S-V-F1 protein appeared equivalent to F1-V in its ability to be recognized by neutralizing antibodies.

Antigen engineering can play a critical role in the protective immunity elicited by Yersinia pestis DNA vaccines.

The use of a DNA immunization approach to deliver protective antigens against Yersinia pestis (Y. pestis) has been successful in previously reported studies. In the current study, the gene designs for V and F1, two well-studied virulent factors serving as main targets for vaccine development, were altered to explore additional options in hopes of improving the protective immunity of DNA vaccines expressing these two antigens. Compared to the wild type V gene DNA vaccines, the use of codon optimized V gene sequences was effective in improving the antigen expression, titers of anti-V antibody responses, and survival against a mucosal lethal challenge. For the F1 DNA vaccine, removal of the N-terminal hydrophobic region was able to improve protective immunity. However, adding a mammalian signal peptide sequence to F1 actually led to reduced protection despite it inducing slightly higher anti-F1 antibody responses. The F1 gene can be fused with a gene coding for YscF, a newly confirmed partial protective antigen for Y. pestis, to produce DNA vaccines that express fused F1 and YscF antigens. One design, in particular, that had YscF fused to the downstream sequence of F1, produced better protection than separate F1 or YscF DNA vaccines, suggesting a potential synergistic effect between these two antigens. Findings from the above studies indicated that there are multiple approaches to optimize the protective immunity for plague DNA vaccines. Most importantly, proper antigen engineering to produce optimal antigen gene inserts in DNA vaccines can clearly play a major role in the future designs of a wide range of DNA vaccines.

Prevention of bubonic and pneumonic plague using plant-derived vaccines.

Yersinia pestis, the causative agent of bubonic and pneumonic plague, is an extremely virulent bacterium but there are currently no approved vaccines for protection against this organism. Plants represent an economical and safer alternative to fermentation-based expression systems for the production of therapeutic proteins. The recombinant plague vaccine candidates produced in plants are based on the two most immunogenic antigens of Y. pestis: the fraction-1 capsular antigen (F1) and the low calcium response virulent antigen (V) either in combination or as a fusion protein (F1-V). These antigens have been expressed in plants using all three known possible strategies: nuclear transformation, chloroplast transformation and plant-virus-based expression vectors. These plant-derived plague vaccine candidates were successfully tested in animal models using parenteral, oral, or prime/boost immunization regimens. This review focuses on the recent research accomplishments towards the development of safe and effective pneumonic and bubonic plague vaccines using plants as bioreactors.

Plants as biofactories for the production of subunit vaccines against bio-security-related bacteria and viruses.

The development of new generation vaccines is an imperative tool to counteract accidental or intended release of bio-threat agents, such as Bacillus anthracis, Yersinia pestis and variola virus, and to control natural outbreaks. In the past few years, numerous data accumulated on the immunogenicity and safety of plant-made vaccines against bio-security-related organisms. In addition, expression levels achieved for these antigenic proteins are practical for the production of sufficient material for large-scale vaccination programs. These data demonstrated that the plant-based approach is feasible for manufacturing recombinant vaccines against bio-terror agents that could be mass-produced at reasonable cost.

Plants as alternative systems for production of vaccines.

Subunit vaccine production is typically associated with bacterial, yeast, insect or mammalian cell culture systems. Plants, however, are emerging as an alternative platform for producing vaccine antigens, and offer some advantages over other recombinant systems. In particular, plant virus-based transient expression systems are suitable for rapid engineering, ease of scale-up and cost-effective production of target antigens. In addition, this system provides an ideal approach for producing large quantities of vaccine antigens in a short period of time, which is particularly important when faced with natural outbreaks or accidental or intended release of bio-threat agents such as Bacillus anthrax and Yersinia pestis. This commentary reviews the production and evaluation of antigens made in plants in an attempt to develop vaccines against B. anthracis and Y. pestis.

[Morphological structure of Yersinia pestis populations (strain EV) in the process of live plague vaccine production]. / Otsenka morfologicheskoi struktury populiatsii Yersinia pestis (shtamm EV) na étapakh prigotovleniia chumnoi zhivoi vaktsiny.

Morphological structure of the population of Yersinia pestis strain EV and the pattern of its changes during deep cultivation and in different stages of the live plague vaccine production was under study. The size range of cells most resistant to external influences was established.